ES2386190T3 - Method for transmitting and receiving a signal and apparatus for transmitting and receiving a signal - Google Patents

Abstract

The present invention relates to method of transmitting and receiving broadcasting signal and a corresponding apparatus. One aspect of the present invention relates to a method of receiving broadcasting signal, wherein a C2 delivery system descriptor including an identifier of a PLP and an identifier of a C2 system in a TS loop of the NIT maps a transport stream to the data PLP in a data slice of the C2 system.

Description

Method for transmitting and receiving a signal and apparatus for transmitting and receiving a signal

Background of the invention

The present invention relates to a method for transmitting and receiving a signal and an apparatus for transmitting and receiving a signal.

Description of the related technique

The present invention relates to a method of broadcasting using a portion of data and Physical Layer Conduction (PLP) that is configured by applying a channel-joining technique in digital cable broadcasting, and a method for efficiently assigning and signaling signals between layers which minimizes change through a new

10 structure, called PLP and portion of data, maximally using a signaling structure that connects layers such as the existing network, service, and packet.

A current digital TV broadcasting transmission technology is advancing for the purpose of deriving maximum efficiency in the same frequency band out of an issue that converts an analog signal into a digital signal. Therefore, from Digital Satellite Video Broadcasting (DVB-S) and Broadcasting

15 Digital Video Terrestrial (DVB-T), Europe defines a transmission standard called DVB-S21T2, and improves the transmission rate between 30% to 50% with respect to the existing scheme through the transmission standard. These are being applied in a practical way.

According to this background, cable broadcasting also proposes new requirements that have been advanced more than Digital Video Cable Broadcasting (DVB-C). Particularly, due to the characteristic

20 in which there is a lot of terrestrial broadcasting or satellite broadcasting, the requirements of DVB-C2 have been defined to increase transmission efficiency while the DVB-S21T2 structure is reused to a maximum. The standardization of DVB-C2 to implement this is ongoing.

As the feature of the DVB-C2, a concept has been introduced that integrates and uses adjacent Radio Frequency (RF) bands through a channel joining scheme while maximally applying the structure of

25 transmission of the existing DVB S21T2, thereby minimizing the expense through a guard frequency. Consequently, the importance of a channel that has the same band becomes less. This is replaced by a concept, called a portion of data of a variable bandwidth.

With reference to Fig. 1, a portion of data having a variable frequency width in a frequency band is seen, and several PLPs are included and transmitted in the data portion (the concept of the PLP has been proposed

30 in DVB-T2). A slot frequency that is a band in which it is impossible to receive a signal can be inserted in the middle.

The data portion configuration information can be obtained by Layer 1 (L1) signaling that has the same information anywhere within a DVB-C2 transmission band, but the detailed content has not been defined. Therefore, when a receiver intends to receive such a "portion" structure

35 data + PLP ", a method to obtain a desired sequence through a portion of data and PLP, and a signaling method to connect a desired sequence to a service packet service need to be defined.

Summary of the invention

The embodiments provide a method for transmitting and receiving a signal and an apparatus for transmitting and receiving a signal capable of efficiently assigning and signaling signals between layers that minimizes the change by a

40 new structure, called PLP and portion of data, using a signaling structure that connects layers such as the existing network, service and package.

Accordingly, the present invention is directed to a method for transmitting and receiving a signal and an apparatus for transmitting and receiving a signal that significantly obviates one or more problems due to the limitations and disadvantages of the related technique.

One aspect of the present invention provides a method for receiving a broadcast signal according to claim 1.

Another aspect of the present invention provides an apparatus for receiving a broadcasting signal according to claim 4.

Yet another aspect of the present invention provides an apparatus for transmitting a broadcast signal according to claim 7.

Still another aspect of the present invention provides an apparatus for transmitting a broadcast signal according to claim 10.

Brief description of the drawings

The accompanying drawings, which are included to provide an additional understanding of the invention and are incorporated into and constitute a part of this application, illustrate the embodiment (s) of the invention and together with the description serve to explain the principle of the invention.

Fig. 1 shows a plot of the data portion structure and Physical Layer Conduction (PLP). Fig. 2 is a conceptual diagram showing the relationship between Physical Layer Conductions (PLP) and services. Fig. 3 shows an example of assignment PLP and service. Fig. 4 shows an example of NIT with detailed syntax. Fig. 5 shows an example of delivery system descriptor C2 (C2dsd) with detailed syntax. Fig. 6 shows an example of assignment PLP and service package. Fig. 7 shows an example of signaling format for bandwidth. Fig. 8 shows an example of a cable modulation scheme. Fig. 9 shows an example of signaling format for each of the guard interval values. Fig. 10 shows an example of signaling format for the FFT size transmission mode. Fig. 11 shows another example of delivery system descriptor C2 (C2dsd) with detailed syntax. Fig. 12 shows an example of signaling format for active OFDM symbol duration values. Fig. 13 shows an example of signaling format for guard interval values. Fig. 14 is a flow chart illustrating a method for receiving a signal in a broadcasting system. Fig. 15 shows an apparatus for receiving the broadcast signal in accordance with an embodiment of the present

invention.

Fig. 16 shows an apparatus for transmitting a broadcast signal according to another embodiment of the present invention. Fig. 17 is a flow chart illustrating a method for transmitting a broadcast signal in accordance with

Another embodiment of the present invention.

Fig. 18 shows an apparatus for receiving a broadcast signal in accordance with another embodiment of the present invention. Fig. 19 is a flow chart illustrating a method of receiving a broadcast signal according to another

realization of the present invention.

Description of the preferred embodiments

Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

In the following description, the term "service" is indicative of any of the broadcast contents that may be transmitted by the signal reception transmission apparatus.

Fig. 2 is a conceptual diagram showing the relationship between Physical Layer Conductions (PLP) and services.

In the case of using a transmission scheme that adopts a PLP, a Layer 1 (L1) signal is received when an arbitrary RF channel is tuned. Consequently, a portion of data is received that has several PLPs in a corresponding region (the left part in Fig. 2). The data portion may have a preamble that includes a first pilot signal (P1) and a second pilot signal (P2).

At this point, the signaling part that identically identifies the entire configuration of a portion of data in all receiving regions is called L1 signaling data, which includes information that includes the number of data portions, the width of data. each portion of data, a configuration of the PLP included in each portion of data, and Layer 2 (L2) signaling data that includes a common PLP. Based on this, by checking the configuration of a c2 system (for example, the data portion + PLP), the PLPs can be divided (the central part in Fig. 2).

A common PLP (or the signaling information of a PLP) can be extracted from the L2 signaling data, in which the common PLP includes Program Specific Information1 Service Information (PSI1SI) data (for example, the Table Information Network (NIT), the Service Description Table (SDT), and the Set Association Table (BAT). From this, you can obtain the information from Network1 Portion of data 1PL1 service. Then, an apparatus for receiving the broadcast signal provides the basic information for tuning the service. Through this, the PLP assignment information to the network, service, and packet (ie, set) is provided (the right part in Fig. 2).

Fig. 3 shows an example of assignment and service PLP.

A configuration of a data portion and a PLP included in the data portion are transmitted to a receiver through the signaling of L1 as shown in the first part of Fig. 3. The signaling data of L1 provides information that It comprises the total number and bands of data portions, the number of the PLPs and the structure information of the PLP included in each portion of the data, and the L2 signaling information included in the PSI1SI.

The signaling of L2 or Network Information Table (NIT) included in a service PLP informs the network information in several Transport Sequences that is transmitted through the C2 system (the central part in Fig. 3). The detailed structure of the NIT can be seen in Fig. 4.

The NIT is configured with several Transport Sequence (TS) information loops. In the present invention, a delivery system descriptor C2 (hereinafter referred to as a C2dsd, see Fig. 5) "is defined to be added to the TS descriptor loop. Then, the NIT is configured to inform through the which the PLP of some portion of data is transmitted by the TS of a corresponding loop, that is, a PLP that corresponds to an identifier of the PLP (plp id) in the c2dsd is transmitted in a portion of data that corresponds to an identifier of the portion of data (slide id) in the C2dsd. This is a structure capable of knowing that the corresponding TS is transmitted through the PLP.

In the TS loop, the identifier of a TS (transport stream id) and the identifier of a network (original nettork id) only divide a corresponding TS. The broadcasting service provided through the TS is signaled through the Service Description Table (SDT). At this point, the transport stream id and the original nettork id of the NIT are connected to the transport stream id pair and the original nettork id of the SDT, and informs through which TS a service list represented as the identifier is provided of a service (service id) of the SDT (the NIT-SDT connection of a center-right part in Fig. 3).

Fig. 6 illustrates that a network, service and packet (ie, set) are connected to the PLP in the same scheme. As described with reference to Fig. 3, the TS is connected to a specific PLP using the plp id of the C2dsd. The connection between an identifier of a network (nettork id) and the TS, and the connection between the identifier of a set (bouquet id) of the BAT and the TS is implemented with respect to the TS identically to the PSI1SI (such as the conventional DVB-SI) existing. In this sense, by introducing the C2dsd in the NIT, the PLP connects to a network, service, and packet through the minimum change, thereby improving the compatibility of PSI1SI.

Fig. 4 shows the detailed syntax of the NIT, and Fig. 5 shows the detailed syntax of the C2dsd. With reference to Fig. 4, the NIT has the syntax of the existing SI as is, and the C2dsd is included in a descriptor loop in a TS loop and is therefore transmitted. Through this, the transport stream id of the TS loop is matched with the plp id and the dslice id of the C2dsd.

The C2dsd of Fig. 5 is configured as follows.

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descriptor tag: This informs what descriptor it is, and has a unique value. However, because a representable list of dvb descriptor with 8 bits is full, this value defines 0x7F and uses a tag extension descriptor (see extension descriptor: chapter 6.3 of EN 300 468 of the ETSI Identification and location of extended descriptor ).

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Lenght descriptor: This reports the entire length of a descriptor.

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descriptor tag extension: This reports the type of a descriptor. A reserved value such as 0x07 can be used arbitrarily for the c2dsd (0x00 to 0x06 are preferred).

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PLP id: This represents the identifier of a PLP to which a sequence represented by a transport stream id is transmitted in the NIT TS loop that includes a descriptor. That is, a PLP id uniquely identifies a PLP of data within a C2 system.

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c2 system id: This is an identifier of a C2 system that represents an independent c2 transmission network. An identifier of a portion of data (slide id) and an identifier of a plp (plp id) are uniquely defined in the identifier of a C2 system (c2 system id). That is, a C2 system id uniquely identifies a C2 system.

To this, the 6 octets are compatible because they are the same as the t2dsd of DVB-T2, and can be reused in the retransmission.

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dslice id: This informs to which portion of data the PLP of a corresponding plp id is transmitted. That is, a slide id uniquely identifies a portion of data within a C2 system.

5 -slice tidth: This informs of a bandwidth over which the data portion of a corresponding id id is transmitted. This can be represented by the carrier number, and can have the carrier number as dslice tidth x 12.

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Bandwidth: This reports a bandwidth that is used in a system (See Fig. 7). Fig. 7 shows an example of signaling format for bandwidth.

10 -Modulation: This reports a cable modulation scheme. As illustrated in Fig. 8, there are options from 16-QAM to 65536-QAM. Fig. 8 shows an example of a cable modulation scheme.

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guard interval: This reports a guard interval (See Fig. 9). Fig. 9 shows an example of signaling format for each of the guard interval values.

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Transmission mode: This reports the FFT size of a transmission signal. A 4k mode is 15 one by default (See Fig. 10). Fig. 10 shows an example of signaling format for FFT size transmission mode.

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center frequency: This reports the representative frequency of a corresponding dslice id. In the case of DVB-C, the center frequency is a value that is encoded through 4-bit BCD encoding and uses MHz as a unit, if necessary, it can be redefined.

20 In addition, when signaling is required for another parameter, addition can be made continuously below.

Then, as another embodiment of the present invention, the C2dsd can be defined as described in Fig. 11. Fig. 11 shows another example of the C2dsd with detailed syntax.

The C2dsd of Fig. 11 is configured as follows.

25-tag descriptor: This 8-bit field informs that it is a descriptor, and has a unique value. However, because a list of representable dvb descriptors with 8 bits is full, this value defines 0x7F and uses a tag extension descriptor.

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lenght descriptor: This 8-bit field reports the entire length of a descriptor.

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descriptor tag extension: This 8-bit field reports the type of a descriptor.

30 -PLP id: This 8-bit field uniquely identifies a PLP of data within a C2 system. This represents the ID of a PLP to which a sequence represented by a transport stream id is transmitted in the NIT TS loop that includes a descriptor.

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data slice id: This 8-bit field uniquely identifies a portion of data within a C2 system. This informs to which portion of data the PLP of a corresponding plp id is transmitted.

35 -c2 system id: This 16-bit field uniquely identifies a C2 system. This represents an independent C2 transmission network. A data slice id and a plp id are defined uniquely in the c2 system id.

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c2 system tuning frequency: This 32-bit field indicates the frequency value. The coding range is from a minimum of 1 Hz (0x00000001) to a maximum of 4,294,967,295 Hz (0xFFFFFFFF). This field of

40 data gives a tuning frequency of a C2 system, in which a complete preamble is transmitted within the tuning window. Generally the c2 system tuning frequency is the center frequency of a C2 system, but it can deviate from the center frequency in case there are slots in this area.

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activate OFDM symbol duration: This 3-bit field indicates the duration of the Multiplex symbol by

45 Orthogonal Frequency Division (OFDM) active and can be described as in Fig. 12. Fig. 12 shows an example of signaling format for the duration values of active OFDM symbols. The duration of the active OFDM symbol can be 448 µm in the 4k FFT mode for systems

8 MHz bandwidth. The duration of the active OFDM symbol can be 597 µm in the 4k FFT mode for 6 MHz bandwidth systems. And, the duration of the active OFDM symbol for

50 6 MHz bandwidth systems can be indicated as 448 x (8 1 6) µs or 597.33 µs more precisely.

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guard interval: This 3-bit field indicates the guard interval and can be described as in Fig. 13. Fig. 13 shows an example of signaling format for guard interval values. The guard interval can be 11128 or 1164.

In the C2dsd described in Fig. 11, the fields from the c2 system tuning frequency field to the reserved field, immediately following the c2 system id field, can occur only once per C2 system. Because the parameters are applicable only to all portions of data transported on a particular C2 system, the presence or absence of that part cannot be derived from the lenght descriptor field. For example, in the absence of fields from the c2 system tuning frequency field to the reserved field, the lenght descriptor can be 0x07, otherwise it applies a higher value.

Next, as another embodiment of the present invention, the C2dsd can be defined except an identifier of a data slice (data slice id) from the descriptor shown in Fig. 11. As described above, the configuration information of the portion of data can be obtained by Layer 1 (L1) signaling that has the same information anywhere within a DVB-C2 transmission band. The signaling data of L1 provides information comprising the total number and bands of the data portions, the number of the PLPs and the structure information of the PLP included in each portion of data. That is, the information related to the portion of data corresponding to the PLP is provided through and is derived from the Layer 1 signaling. Therefore, a data portion identifier in the C2dsd can be omitted when the identifier of the Portion of data that corresponds to the PLP identifier is provided through and derived from the Layer 1 signaling.

Therefore, the delivery system descriptor C2 (C2dsd) can be defined with the fields descriptor tag, descriptor lenght, descriptor tag extension, plp id, and c2 system id. The C2dsd assigns a Transport Sequence that is signaled with the NIT, and directs the TS descriptor loop, to the corresponding C2 system (C2 system id) and the PLP (plp id) that transports this Transport Sequence within the C2 system . That is, the descriptor of the delivery system C2 (C2dsd) in the TS loop of the NIT assigns the transport sequences to the data PLPs in data portions of C2 systems. And the C2dsd can also comprise the c2 system tuning frequency field, the OFDM symbol duration active field described in Fig. 12, and the guard interval field described in Fig. 13.

Fig. 14 is a flow chart illustrating a method for receiving a signal in the broadcasting system to which the invention is applied.

First, with reference to Fig. 14, when a tuner tunes a channel, a preamble signal (S1401 and S1403) is introduced. A receiver receives the L1 signaling data that is transmitted identically independently of a tuning frequency as shown in Figs. 1 and 2.

Then, from the signaling data of L1, the structure of the entire data portion, the structure of the PLPs included in each data portion, and the information of signaling data of L2 are obtained (S1405).

A PLP that includes the L2 signaling data is received. Here, (S1407) PSI1SI information such as NIT, SDT, and BAT is included.

When the NIT is received, the receiver checks an identifier of a network (nettork id). Then, the receiver analyzes a TS loop to check the connection information of the ID id slide of the C2dsd and the transport stream id of each TS. Through this, (S1409, S1411, and S1413) a network-TS-PLP data portion structure and tuning information are obtained.

When the SDT is received, the receiver checks a TS-service connection structure through the original nettork id and the transport stream id as shown in Fig. 6 (S1421 and S1423).

When the BAT is received, the receiver checks a TS-packet connection structure (ie set) through the original nettork id and the transport stream id as shown in Fig. 6 (S1431 and S1433).

When all the necessary PSI1SI information is obtained, the receiver finds a transport stream id that corresponds to the service id of the desired service, in the SDT and finds a PLP and portion of data to which the corresponding TS is transmitted in the c2dsd of the NIT for tuning (S1415).

When tuned to a corresponding portion of data, the receiver decodes the TS of a desired transport stream id through the PLP of a corresponding plp id. The receiver starts decoding the A1V sequences and provides the service (S1417 and S1419).

Fig. 15 shows an apparatus for receiving the broadcast signal in accordance with an embodiment of the present invention.

With reference to Fig. 15, the receiver of this embodiment includes an input circuit unit 1510, service management unit 1520. The File Delivery processing unit on Unidirectional Transport

(FLUTE) 1530, metadata processing unit 1540, Intermediate Support processing unit (M1 /) 1550, Audio1Video (A1V) 1560 processing unit, Personal Video Recorder (PVR) 1570 processing unit , and the processing unit Input1 Output (I1O) 1580.

The input circuitry unit 1510 includes a tuner1 modem 1511, a temporary store of GSE 1512, a syntactic analyzer of GSE 1513, a temporary store1filter of TS 1514, a temporary store of Audio1Video1Data (A1V1D) 1515, a PSI1SI 1516 store, a demultiplexer1analyzer PSI1SI 1517 syntactic, and a syntactic filter1 of IP1Port 1518. The input circuit unit 1510 receives a broadcast signal and decodes the received signal in a suitable type according to a transmission scheme to take out a Generic Sequence Encapsulation packet. (GSE) or Transport Sequence (TS).

The tuner 1 modem 1511 receives a broadcast signal and outputs the received signal in one type of sequence. In the case of DVB-C2, the GSE or TS is removed. The GSE 1512 temporary store temporarily stores and the GSE 1513 temporary analyzer decodes the GSE sequence to output it as an IP packet. The temporary storage1 TS filter 1514 temporarily stores and filters the TS sequence. The Audio1Video1Data 1515 temporary store temporarily stores non-PSI1SI data between the TS sequences and transmits the temporarily stored data to a 1560 transport sequence syntax analyzer. The PSI1SI 1516 temporary store temporarily stores in the TS sequence and the syntactic analyzer demultiplexer PSI1SI 1517 decodes the temporarily stored signal to transfer the decoded signal to a service manager 1521. The syntactic filter1 of IP1Port 1518 filters a packet corresponding to a specific IP1Port of service according to the service access information request of the service manager 1521 At this point, an IP packet that is decoded for each address in accordance with the control of the service manager 1521 is transferred to the FLUTE 1530 processing unit.

The service management unit 1520 includes the service manager 1521 and a Channel Database (DB) 1523. The service management unit 1520 manages total system control for the service provided by a service provider.

The service manager 1521 manages the total services according to the list of services and the access information that is transferred as metadata. The main functions of the service manager 1521 are as follows.

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The service manager 1521 processes the tuner control information such as the data portion and the PLP, which are transferred in the PSI1SI.

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The service manager 1521 processes the service access information that is transferred from an SDP 1532 syntactic analyzer.

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The service manager 1521 provides the filtering information in the syntactic filter of IP1Port 1518 according to the service access information. At this point, the service manager 1521 also controls to which part of the processing a packet taken should be transferred according to the filtering (FLUTE, security or A1V).

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The service manager 1521 notes that logical processing of Extensible Style Sheet Language Transformations (XSLT) should be performed when metadata is converted through the system into a common metadata schema.

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The service manager 1521 requires, receives and processes all kinds of service information necessary for a common metadata manipulator 1542, and selects and stores only the information necessary for the database (DB) of channel 1523.

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The service manager 1521 processes the service-related operations (for example, a channel change operation) necessary in an Electronic Program Guide (EPG) operation.

The channel database 1523 stores content related to management1change1 access between the information related to the service for the efficient operation of the service manager 1521, and the contents are introduced and removed frequently.

The FLUTE 1530 processing unit includes a FLUTE syntactic analyzer and a Gzip1BiM 1531 decoder, Session Description Protocol (SDP) 1532 syntactic analyzer, a 1533 metadata temporary store, and a 1534 syntactic file analyzer. The FLUTE processing unit 1530 decodes a file that is encoded according to a FLUTE protocol and transfers the decoded file to a corresponding processing part according to each content format.

The FLUTE syntactic analyzer and the Gzip1BiM 1531 decoder decode a file that is encoded based on the FLUTE protocol, and at this point, it performs decompression according to a compressed scheme to extract a file. The content type of the extracted file can be checked in the form of the File Description Table (FDT) content of the FLUTE protocol. Therefore, each file is transmitted to the SDP syntactic analyzer

1532, the temporary metadata store 1533, or the temporary file store 1534 based on the type of content. The SDP 1532 syntactic parser decodes an SDP file that is the file that represents the access information and transfers the decoded result to the service manager 1521.

Temporary metadata store 1533 temporarily stores metadata that is a type of Extended Markup Language (XML) file that represents the total information associated with the content service. Temporary metadata store 1533 also transfers the temporarily stored metadata to an XSLT 1541 processor to convert the metadata into a common metadata format. The temporary file store 1534 temporarily stores several files that are used on a buffer, and stores the files temporarily stored in a file storage 1551 of the intermediate support processing unit 1550. These files can be used by a support engine Intermediate (M1 /) 1552. The temporary file store 1534 may temporarily store the files together with a file that is transmitted through a Digital Storage Media Command and Control (DSM-CC) 1562 part of a syntactic parser. Sequence of Transportation (TS) 1561.

The metadata processing unit 1540 includes the XSLT 1541 processor, the common metadata manipulator 1542, and metadata storage 1543. The metadata processing unit 1540 converts the metadata that is transferred from the FLUTE 1530 processing unit into a format of common metadata, which is a common format, stores the converted metadata. The metadata processing unit 1540 searches for the relevant content, and provides the desired result according to the request of each part.

The XSLT 1541 processor converts metadata into common metadata using the XSLT based on each transmission scheme, in which the metadata can be different from each other according to each transmission scheme. The metadata storage 1543 stores the common metadata, and performs a search to transfer the desired result in accordance with the request of the common metadata manipulator 1542. The common metadata manipulator 1542 searches the metadata according to various requests for information associated with the service, event and access information, and transfers the search result to the service manager 1521, an EPG manager 1581, and a security manager 1569. The common metadata manipulator 1542 can store the metadata in connection with the data of PVR in accordance with the request of a 1576 PVR manager.

The intermediate support processing unit 1550 includes a file storage 1551 and the intermediate support engine (M1 /) 1552. The intermediate support processing unit 1550 loads a file that is transferred from the FLUTE 1530 processing unit to drive and Run an appropriate application.

The file storage 1551 stores all types of files to be used in the intermediate support engine 1552, and transmits a necessary file according to a request from the intermediate support engine 1552. The intermediate support engine 1552 drives the intermediate support such as the Advanced Common Applications Platform (ACAP), Open Cable Applications Platform (OCAP), Multimedia Home Platform (MHP), and the Group of Experts for Multimedia and Hypermedia Information Coding (MHEG), and receives a necessary file from 1551 file storage to display a drive application on a screen through a 1584 video post processor.

The audio processing unit1video (A1V) 1560 includes the transport sequence syntactic analyzer 1561, the desalterizer 1566, an audio decoder 1567, a video decoder 1568, the security manager 1569, and a part of the Time Clock System (STC) 1591. The audio processing unit1video 1560 decodes an A1V sequence, processes a randomizer, and displays it on a screen to be synchronized.

The transport sequence (TS) 1561 syntactic analyzer includes the DSM-CC 1562 part, a Rights Management Message (EMM) part 1563, a sequence part of A1V 1564, and a PCR time stamp 1565. The syntactic analyzer of the transport sequence 1561 synthetically analyzes a sequence that is introduced into the TS type of an MPEG-2 system to divide the sequence into an audio sequence, a video sequence, a data sequence, and timing information according to the types of sequences. The part of DSM-CC 1562 synthetically analyzes a sequence of DSM-CC data. The part of EMM 1563 synthetically analyzes a rights management message that is a signal related to the Conditional Access System (CAS). The sequence part of A1V 1564 synthetically analyzes an audio1video sequence. The PCR time stamp part 1565 synthetically analyzes a PCR signal.

The randomizer 1566 randomizes a randomized sequence based on a randomization key value and the necessary parameters are transmitted from the security manager 1569. The security manager 1569 manages the security information associated with CAS such as the Conditional Access Table (CAT ) between PSI1SI, and transmits the randomized information to the randomizer 1566. The audio decoder 1567 decodes an audio sequence and the video decoder 1568 decodes a video sequence. The System Time Clock (STC) part 1591 provides a reference clock to synchronize a playback speed with a transmitted sequence. The part of STC 1591 is synchronized with the clock of a server using the clock recovery information received from the PCR time stamp part 1565 of the TS 1561 syntactic analyzer. In a PVR reproduction, the part of STC 1591 receives a clock from a 1572 charge controller.

The PVR 1570 processing unit includes an Audio1Video (A1V) 1571 storage, the 1572 charge controller, a 1573 desalterizer, a 1574 discharge controller, a 1575 randomizer, and the 1576 PVR manager. The PVR processing unit 1570 is a part associated with a function related to the PVR (or DVR), ie the storage and reproduction of a sequence.

The PVR 1576 manager controls the operations related to the PVR. That is, the PVR manager 1576 controls the discharge controller 1574 and the charge controller of the PVR processing unit 1570, that is, controls the storage, playback and recording backup. The PVR manager 1576 communicates with the intermediate support motor 1552 for data broadcast recording. The PVR 1576 manager communicates with a 1582 User Interface (UI) manager for the PVR UI. The PVR manager 1576 is connected to the common metadata manipulator 1542 to store the metadata connected to the stored content. The download controller 1574 adds information such as a timestamp and a random access point to an A1V sequence in the sequence recording, and stores it. Randomizer 1575 performs randomization to protect the content in the sequence recording. The A1V 1571 storage stores an A1V sequence. The randomizer 1573 performs the randomization to reproduce, to the randomized content that has been randomized to protect the content. The load controller 1572 transmits information such as the time stamp and the random access point to the STC 1591 and the PVR 1576 manager, and transmits a sequence to the Audio decoder 1567 and the video decoder 1568.

The I1O 1580 processing unit includes the EPG 1581 manager, the UI manager 1582, the user interface 1583, the rear video processor 1584, and the rear audio processor 1585. The I1O 1580 processing unit is related with a user input and an A1V output.

The EPG 1581 manager receives the metadata associated with the screen of an EPG from the common metadata manipulator 1542, processes the metadata in a suitable format, and combines the processed metadata with a video sequence or an intermediate support application through the UI 1582 manager to display the combined data on a screen. The UI manager 1582 interprets a user input and requests the necessary operations in connection with the service manager 1521, the EPG manager 1581, and the PVR manager 1576. The user interface 1583 transmits a user input to a system through the 1582 UI manager. The 1584 post video processor combines a video stream, an intermediate support application, an EPG, and all kinds of UI gadgets to display the combined result on a screen. The rear audio processor 1585 outputs an audio sequence as sound in connection with the function such as volume control or mute.

Fig. 16 shows an apparatus for transmitting the broadcast signal in accordance with another embodiment of the present invention.

Referring to Fig. 16, the transmitter according to this embodiment includes an input processor 1601, an encoding and modulation unit 1602, a frame former 1603, a modulator 1604, and an analog processor 1605.

The inputs may comprise a series of MPEG-TS sequences or Generic Sequence Encapsulation (GSE) sequences. The input processor 1601 can add transmission parameters to the input sequence and carry out the planning for the coding and modulation unit 1602.

The coding and modulation unit 1602 can add redundancy and interleaved data for the correction of transmission channel errors. That is, the encoding and modulation unit 1602 can be configured to encode a transport sequence using an error correction coding scheme and interleaving bits of the transport sequence encoded with error correction. For example, the encoding and modulation unit 1602 may be an Interleaved Bit Coding and Modulation (BICM) unit.

The frame former 1603 can form frames by adding physical layer and pilot signaling information. That is, the frame former 1603 can be configured to assign the interleaved bits of the transport sequence to symbols of a physical layer conduit (PLP). The frame builder 1603 can be configured to assign the PLP symbols to a signal frame, and arrange the layer 2 information including a network information table (NIT) that has a physical layer conduction identifier (PLP) id) and an identifier of a C2 system (C2 system id) that corresponds to the transport sequence in the signal frame.

Modulator 1604 can perform modulation on input symbols in efficient methods. For example, modulator 1604 can be configured to modulate the signal frame by the Orthogonal Frequency Division Multiplexing (OFDM) method.

Analog processor 1605 can perform several processes to convert digital input signals into analog output signals.

In the embodiment of the present invention, a delivery system descriptor C2 (C2dsd) that includes the identifier of a physical layer conduit (PLP id) and an identifier of a C2 system (C2 system id) in a TS loop of the NIT assigns a transport sequence to the data PLP in a portion of system data

C2 In the embodiment, the information related to the PLP corresponding to the portion of data can be provided through and derived from the layer 1 signaling.

That is, as described above, delivery system descriptor C2 (C2dsd) assigns a transport sequence that is signaled with the NIT, and directs the TS descriptor loop, to the corresponding C2 system (C2 system id) and the PLP (PLP id) that transports this transport sequence within the C2 system. And, the information related to the portion of data in the C2 system is provided through and derived from the signaling of layer 1.

As described above, the delivery system descriptor C2 (C2dsd) may comprise the fields descriptor tag, descriptor lenght, descriptor tag extension, plp id, and C2 system id. The delivery system descriptor C2 (C2dsd) can also comprise frequency tuning fields of the C2 system, duration of the active OFDM symbol (active OFDM symbol duration), and guard interval (guard interval).

In this example, the duration of the active OFDM symbol can be 448 µ1 (in 4k FFT mode for CATV systems of 8MHz bandwidth) or 597 µ1 (in 4k FFT mode for CATV systems of width of 6MHz band). And, the duration of the active OFDM symbol for 6MHz bandwidth systems can be

indicate as 448 x (816) µ1 or 597.33 µ1 more accurately. Then, in this example, the value of the guard interval can be 11128 or 1164.

Fig. 17 is a flow chart illustrating a method for transmitting the broadcast signal in accordance with another embodiment of the present invention.

With reference to Fig. 17, a transport sequence is converted to a physical layer conduit (PLP) (S1701). Then, the PLP symbols are assigned to a signal frame and the information in layer 2 is arranged in a signal frame preamble (S1703). Layer 2 may include a network information table (NIT) that has an identifier of a physical layer conduit (PLP id) and an identifier of a C2 system (C2 system id) corresponding to the transport sequence in the network frame. signal.

The signal frame is modulated (S1705), for example, by an Orthogonal Frequency Division Multiplexing (OFDM) method, and the modulated signal frame is transmitted (S1707).

In this embodiment of the present invention, a delivery system descriptor C2 (C2dsd) that includes the identifier of a physical layer conduit (PLP id) and the identifier of a C2 system (C2 system id) in a TS loop of The NIT assigns the transport sequence to the data PLP in a data portion of the C2 system. In the embodiment, information related to the PLP corresponding to the portion of data through and derived from the layer 1 signaling can be provided.

That is, as described above, the delivery system descriptor C2 (C2dsd) assigns a transport sequence that is signaled with the NIT, and directs the TS descriptor loop, to the corresponding C2 system (C2 system id) and the PLP (PLP id) that transports this transport sequence within the C2 system. And, the information related to the portion of data in the C2 system is provided through and derived from the signaling of layer 1.

As described above, the delivery system descriptor C2 (C2dsd) may comprise the fields descriptor tag, descriptor lenght, descriptor tag extension, plp id, and C2 system id. The delivery system descriptor C2 (C2dsd) may further comprise frequency tuning fields of the C2 system, duration of the active OFDM symbol (active OFDM symbol duration), and guard interval (guard interval).

In this example, the duration of the active OFDM symbol can be 448 µ1 (in 4k FFT mode for CATV systems of 8MHz bandwidth) or 597 µ1 (in 4k FFT mode for CATV systems of width of 6MHz band). And, the duration of the active OFDM symbol for 6MHz bandwidth systems can be

indicate as 448 x (816) µ1 or 597.33 µ1 more accurately. Then, in this example, the value of the guard interval can be 11128 or 1164.

Fig. 18 shows an apparatus for receiving a broadcast signal in accordance with another embodiment of the present invention.

With reference to Fig. 18, the receiver according to this embodiment includes an analog processor 1801, a demodulator 1802, a syntactic frame analyzer 1803, a decoding and demodulation unit 1804, and an output processor 1805.

The received signal is converted into a digital signal in the analog processor 1801. The demodulator 1802 converts the signal received from the analog processor 1801 into data in the frequency domain. That is, demodulator 1802 can be configured to demodulate received signals including a signal frame, for example, by use of an Orthogonal Frequency Division Multiplexing (OFDM) method, and output the signal frame.

The syntactic frame analyzer 1803 can extract pilots and headers and allow the selection of service information that needs to be encoded. That is, the syntactic frame analyzer 1803 can be configured to synthetically analyze a network information table (NIT) that includes an identifier of a physical layer conduction (PLP id) and an identifier of a C2 system (C2 system id) from the information in layer 2 of the signal frame, and obtain the PLP in the signal frame corresponding to the PLP id and the C2 system id.

The decoding and demodulation unit 1804 can correct errors in the transmission channel. The decoding and demodulation unit, for example, a BICM demodulation unit can be configured to obtain a transport sequence by converting the PLP. The output processor 1805 can restore the originally transmitted service sequence and timing information.

In this embodiment of the present invention, a delivery system descriptor C2 (C2dsd) that includes the identifier of a physical layer conduit (PLP id) and the identifier of a C2 system (C2 system id) in a TS loop of The NIT assigns the transport sequence to the data PLP in a data portion of the C2 system. In the embodiment, information related to the PLP corresponding to the portion of data through and derived from the layer 1 signaling can be provided.

That is, as described above, the delivery system descriptor C2 (C2dsd) assigns a transport sequence that is signaled with the NIT, and directs the TS descriptor loop, to the corresponding C2 system (C2 system id) and the PLP (PLP id) that transports this transport sequence within the C2 system. And, the information related to the portion of data in the C2 system is provided through and derived from the signaling of layer 1.

As described above, the delivery system descriptor C2 (C2dsd) in the NIT may comprise the fields descriptor tag, descriptor lenght, descriptor tag extension, plp id, and C2 system id. The delivery system descriptor C2 (C2dsd) may further comprise frequency tuning fields of the C2 system, duration of the active OFDM symbol (active OFDM symbol duration), and guard interval (guard interval).

In this example, the duration of the active OFDM symbol can be 448 µ1 (in 4k FFT mode for CATV systems of 8MHz bandwidth) or 597 µ1 (in 4k FFT mode for CATV systems of width of 6MHz band). And, the duration of the active OFDM symbol for 6MHz bandwidth systems can be

indicate as 448 x (816) µ1 or 597.33 µ1 more accurately. Then, in this example, the value of the guard interval can be 11128 or 1164.

Fig. 19 is a flow chart illustrating a method of receiving a broadcast signal in accordance with another embodiment of the present invention.

With reference to Fig. 19, a signal according to a signal frame is received (S1901). Then the received signal is demodulated (S1903), for example, by using an Orthogonal Frequency Division Multiplexing (OFDM) method.

Layer 2 information that includes the network information table (NIT) is obtained from the signal frame (S1905), and the NIT that includes an identifier of a physical layer conduction identifier (PLP id) and a The identifier of a C2 system (C2 system id) is analyzed syntactically from the information in layer 2 of the signal frame (S1907).

The PLP in the signal frame corresponding to the identifier of a physical layer conduit (PLP id) and an identifier of a C2 system (C2 system id) is obtained (S1909), and a transport sequence is obtained (S1911) to which the PLP is converted.

In this embodiment of the present invention, a delivery system descriptor C2 (C2dsd) that includes the identifier of a physical layer conduit (PLP id) and the identifier of a C2 system (C2 system id) in a TS loop of The NIT assigns the transport sequence to the data PLP in a data portion of the C2 system. In the embodiment, the information related to the PLP corresponding to the portion of data can be provided through and derived from the layer 1 signaling.

That is, as described above, the delivery system descriptor C2 (C2dsd) assigns a transport sequence that is signaled with the NIT, and directs the TS descriptor loop, to the corresponding C2 system (C2 system id) and the PLP (PLP id) that transports this transport sequence within the C2 system. And, the information related to the portion of data in the C2 system is provided through and derived from the signaling of layer 1.

As described above, the delivery system descriptor C2 (C2dsd) may comprise the fields descriptor tag, descriptor lenght, descriptor tag extension, plp id, and C2 system id. The delivery system descriptor C2 (C2dsd) may further comprise frequency tuning fields of the C2 system, duration of the active OFDM symbol (active OFDM symbol duration), and guard interval (guard interval).

In this example, the duration of the active OFDM symbol can be 448 µ1 (in 4k FFT mode for CATV systems of 8MHz bandwidth) or 597 µ1 (in 4k FFT mode for CATV systems of width of 6MHz band). And, the duration of the active OFDM symbol for 6MHz bandwidth systems can be

indicate as 448 x (816) µ1 or 597.33 µ1 more accurately. Then, in this example, the value of the guard interval 5 can be 11128 or 1164.

As described above, the present invention provides information associated with the data portion and PLP to the receiver through a PSI1SI signaling scheme in a cable DTV broadcasting scheme using a channel joining scheme, and thus it can include the data portion and the PLP in the existing network-service-packet connection structure of the existing PSI1SI while the maximum

10 connection structure. The present invention can maximize the applicability of a PSI1SI controller in the existing system.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the invention.

Claims (12)

1. A method for receiving a broadcast signal, the appropriate method for: receiving a signal comprising a signal frame, in which the signal frame comprises one or more portions of data that carry a Physical Layer Conduction, PLP, and one or more preamble symbols that carry Layer 1 signaling data, L1, for the data portions, and the preamble symbols are divided in the frequency direction into at least two blocks of L1 of the same bandwidth; obtain information from Layer 2, L2, which includes the network information table, NIT, of the signal frame; obtain the NIT that includes an identifier of a physical layer conduction (PLP id) and an identifier of a C2 system (C2 system id) from the information of L2 obtained; obtain the PLP corresponding to the PLP identifier and the C2 system identifier included in the NIT; Y obtain a transport sequence, TS, to which the PLP is assigned, wherein a descriptor of the delivery system C2 that includes the identifier of the PLP and the identifier of the system C2 in a TS loop of the NIT assigns transport sequences to the PLPs in portions of data of the systems C2.

2.

The method according to claim 1, wherein the NIT includes an identifier of the transport sequence and an identifier of a network.

3.

The method according to claim 1 or claim 2, wherein the data portions have an arbitrary bandwidth in the direction of the frequency in the signal frame.

Four.

An apparatus for receiving a broadcasting signal, the apparatus comprising:

means for receiving a signal comprising a signal frame, in which the signal frame comprises one or more portions of data that carry a Physical Layer Conduction, PLP, and one or more preamble symbols that carry Layer 1 signaling data , L1, for the data portions, and the preamble symbols are divided in the frequency direction into at least two blocks of L1 of the same bandwidth; means (1803) for obtaining a network information table, NIT, which includes an identifier of a physical layer conduit (PLP id) and an identifier of a C2 system (C2 system id) of the Layer 2, L2 information, of the signal frame, and obtain the PLP corresponding to the PLP identifier and the C2 system identifier included in the NIT; Y means (1804) for obtaining a transport sequence, TS, to which the PLP is assigned, wherein a descriptor of the delivery system C2 that includes the identifier of the PLP and the identifier of the system C2 in a TS loop of the NIT assigns transport sequences to the PLPs in portions of data of the systems C2.

5.

The apparatus according to claim 4, wherein the NIT includes an identifier of the transport sequence and an identifier of a network.

6.

The apparatus according to claim 4 or claim 5, wherein the data portions have an arbitrary bandwidth in the direction of the frequency in the signal frame.

7.

 A method for transmitting a broadcast signal, the method comprising:

forming a signal frame comprising one or more pieces of data that carry a Physical Layer Conduction, PLP, and one or more preamble symbols that carry Layer 1, L1 signaling data, for the data portions, in which the Preamble symbols are divided in the frequency direction into at least two blocks of L1 of the same bandwidth, and the signal frame comprises a layer 2 information that includes a network information table (NIT) having an identifier of a physical layer conduit (PLP id) and an identifier of a C2 system (C2 system id) corresponding to a transport sequence, TS, in the signal frame; modulate the signal frame by an Orthogonal Frequency Division Multiplexing method, OFDM; Y transmitting the modulated signal frame, in which a descriptor of the delivery system C2 that includes the identifier of the PLP and the identifier of the system C2 in a TS loop of the NIT assigns transport sequences to the PLPs in portions of data from C2 systems. 8. The method according to claim 7, wherein the NIT includes an identifier of the transport sequence and an identifier of a network.

9.

The method according to claim 7 or claim 8, wherein the data portions have an arbitrary bandwidth in the direction of the frequency in the signal frame.

10.

 An apparatus for transmitting a broadcast signal, the transmitter comprising:

means (1603) for forming a signal frame comprising one or more pieces of data that 10 carry a Physical Layer Conduction, PLP, and one or more preamble symbols that carry Layer 1, L1 signaling data for the data portions, in which the preamble symbols are divided into the frequency direction by at least two blocks of L1 of the same bandwidth, and the signal frame comprises a layer 2 information, L2, which includes a network information table, NIT, which has an identifier of a physical layer conduction (PLP id) and an identifier of a C2 system 15 (C2 system id) corresponding to a transport sequence, TS, in the signal frame; Y means (1604) for modulating the signal frame by means of an Orthogonal Frequency Division Multiplexing method, OFDM, in which a descriptor of the delivery system C2 that includes the identifier of the PLP and the identifier of the system C2 in a TS loop of the NIT assigns transport sequences to the PLPs in portions of data 20 of the C2 systems.

eleven.

The apparatus according to claim 10, wherein the NIT includes an identifier of the transport sequence and an identifier of a network.

12.

The apparatus according to claim 10 or claim 11, wherein the data portions have an arbitrary bandwidth in the direction of the frequency in the signal frame.

signal �in